A non-volatile semiconductor memory device includes an electrically data rewritable non-volatile semiconductor memory cell and a write circuit for writing data in the memory cell, the write circuit writing a data in the memory cells by supplying a write voltage Vpgm and a write control voltage VBL to the memory cell, continuing the writing of the data in the memory cell by changing the value of the write control voltage VBL in response to an advent of a first write state of the memory cell and inhibiting any operation of writing a data to the memory cell by further changing the value of the write control voltage VBL to Vdd in response to an advent of a second write state of the memory cell.

A nonvolatile memory device includes a peripheral circuit region and a memory cell region vertically connected with the peripheral circuit region, the peripheral circuit region including at least one first metal pad, and the memory cell region including at least one second metal pad directly connected with the at least one first metal pad. A method of programming the nonvolatile memory device incudes: receiving a programming command, data for a plurality of pages, and an address corresponding to a selected word-line; programming the data for one of the pages to an unselected word-line; reading data of a previously programmed page from the selected word-line; and programming the data for the remaining pages and the data of the previously programmed page to the selected word-line.

A data storage device can detect for a failure in decoding of an x-bit row address and/or a y-bit column of an (x+y)-bit address. The data storage device decodes the x-bit row address and/or the y-bit column address to provide wordlines (WLs) and/or bitlines (BLs) to access one or more cells from among a memory array of the data storage device. The data storage device compares one or more subsets of the WLs and/or of the BLs to each other to detect for the failure. The data storage device determines the failure is present in the decoding of the x-bit row address and/or the y-bit column of the (x+y)-bit address when one or more WL and/or BL from among the one or more subsets of the WLs and/or the BLs differ.

A memory device that includes a plurality of memory cells arranged in rows and columns, a plurality of bit lines each connected to one of the columns of memory cells, and a plurality of differential sense amplifiers each having first and second inputs and an output. For each of the differential sense amplifiers, the differential sense amplifier is configured to generate an output signal on the output having an amplitude that is based upon a difference in signal amplitudes on the first and second inputs, the first input is connected to one of the bit lines, and the second input is connected to another one of the bit lines. Alternately, one or more sense amplifiers are configured to detect signal amplitudes on the bit lines, and the device includes calculation circuitry configured to produce output signals each based upon a difference in signal amplitudes on two of the bit lines.

Multiple (multi-) level cell (MLC) non-volatile (NV) memory (NVM) matrix circuits for performing matrix computations with multi-bit input vectors are disclosed. An MLC NVM matrix circuit includes a plurality of NVM storage string circuits that each include a plurality of MLC NVM storage circuits each containing a plurality of NVM bit cell circuits each configured to store 1-bit memory state. Thus, each MLC NVM storage circuit stores a multi-bit memory state according to memory states of its respective NVM bit cell circuits. Each NVM bit cell circuit includes a transistor whose gate node is coupled to a word line among a plurality of word lines configured to receive an input vector. Activation of the gate node of a given NVM bit cell circuit in an MLC NVM storage circuit controls whether its resistance is contributed to total resistance of an MLC NVM storage circuit coupled to a respective source line.

A series of programming pulses, where the individual pulses are identified by a pulse number, is used to program a page of memory cells in parallel. After receiving a pulse, the memory cells under verification are verified to determine if they have been programmed to their respective target states. The memory cells that have been verified are inhibited from further programming while those memory cells not verified will be further programmed by subsequent programming pulses. The pulsing, verification and inhibition continue until all memory cells of the page have been program-verified. Each verify level used in the verification is a function of both the target state and the pulse number. This allows adjustment of the verify level to compensate for changes in sensing, including those due to variation in source line loading during the course of programming.

A data storage device can detect for a failure in decoding of an x-bit row address and/or a y-bit column of an (x+y)-bit address. The data storage device decodes the x-bit row address and/or the y-bit column address to provide wordlines (WLs) and/or bitlines (BLs) to access one or more cells from among a memory array of the data storage device. The data storage device compares one or more subsets of the WLs and/or of the BLs to each other to detect for the failure. The data storage device determines the failure is present in the decoding of the x-bit row address and/or the y-bit column of the (x+y)-bit address when one or more WL and/or BL from among the one or more subsets of the WLs and/or the BLs differ.

A memory programmer apparatus may include a first-level programmer to program a first-level cell portion of a multi-level memory in a first pass, a coarse programmer to coarse program a second-level cell portion of the multi-level memory in the first pass, wherein the second-level cell portion includes more levels than the first-level cell portion, and a fine programmer to fine program the second-level cell portion of the multi-level memory in a second pass from data programmed in the first-level cell portion in the first pass.

A controlling method of a semiconductor device provided with a memory array including a plurality of complementary cells, each cell including a first memory element and a second memory element, for holding binary data depending on a difference of threshold voltage therebetween, the controlling method comprising: performing a prewrite procedure that writes 0 or 1 to both of the first memory element and the second memory element.

According to an embodiment, a semiconductor memory device includes a plurality of word lines, a plurality of bit lines, a plurality of memory cells, a word line driving circuit, a sense amplifier circuit, and a controller. The memory cell connected to the selected word line is written with data using a write sequence including a plurality of write loops each including a write operation of applying a write voltage to the selected word line by the word line driving circuit and a verify operation of detecting data of the memory cell by the sense amplifier circuit.

The controller determines an (n+k)-th (where n is an integer not less than 1 and k is an integer not less than 2) verify operation based on comparison between an n-th verify operation and an (n+1)-th verify operation in the write sequence.